KR100232565B1 - Water supplier - Google Patents

Abstract

[purpose]

When the tapping temperature does not reach the set temperature even when the gas burner burns at the allowable maximum combustion amount, a hot water heater for reducing the amount of water passing through the bypass pipe is provided.

[Resolution]

Combustion control means for controlling the combustion of the gas burner 4 so that the tapping temperature detected by the tapping temperature thermistor 21 coincides with the set temperature, and the tapping temperature is set even if the gas burner is burned with the maximum allowable combustion amount. In the hot water heater equipped with a water quantity control means for reducing the quantity of the bypass pipe 12 through the quantity control device 13 while keeping the quantity of the heat exchange engine 10 constant when the quantity is not reached, The drain generation is monitored by the detection temperature detected by the heat exchanger thermistor 19 of the heat exchanger tube 10, and when the drain generation or the occurrence of the drainage is detected, the quantity of the bypass pipe 12 is changed to the quantity control device 13. Increase to prevent drainage.

Description

Water heater

The present invention relates to a hot water heater.

In a hot water heater, in which a heat exchanger having a water supply pipe is heated with combustion heat of a gas burner to heat and water the water flowing in the water supply pipe, the tapping temperature sensor detects the tapping temperature, and the gas is heated so that the tapping temperature matches the set temperature set by the user. It is known to the public to control the combustion of burners. In this case, the combustion control of the gas burner calculates the required combustion amount of the gas burner necessary to match the tapping temperature with the set temperature according to, for example, the detected tapping temperature or the water flow rate of the water supply pipe, and burns the gas burner with the required combustion amount. By controlling the amount of air supplied to the gas burner or the amount of fuel supplied to the gas burner.

In this type of hot water heater, a bypass pipe branched from the water supply pipe on the upstream side of the heat exchanger and joined to the water supply path on the downstream side of the heat exchanger is provided to the water heated in the heat exchanger. It is known to combine unheated water and tap water in a bypass tube. Thus, the hot water heater with the bypass pipe has the following advantages. In other words, when the total amount of hot water to be heated in the heat exchanger is low, the combustion amount of the gas burner is lowered when the set temperature is low, and thus the temperature of the fan of the heat exchanger is relatively low. Condensation forms on a fan or the like, so-called drain is generated. The drain is not preferable because it causes deterioration of the heat exchanger and also causes the combustion chamber supply and exhaust passage to be blocked. However, in the hot water heater, in which water heated in a heat exchanger is joined by tapping water that is not heated in a bypass pipe, the gas burner is controlled to be burned so that the temperature after the joining coincides with the set temperature. Even if low, the burn rate of the gas burner is controlled to be relatively high. Therefore, the temperature of a heat exchanger can be made high and generation | occurrence | production of a drain can be suppressed.

Thus, in a hot water heater equipped with a bypass pipe, even if it burns with the allowable maximum combustion amount of a gas burner, a tapping temperature (hot water temperature in a downstream hot water supply pipe rather than a confluence place of a bypass pipe and a hot water supply pipe) does not reach a set temperature. If not, the present invention is considered by the inventors of the water heater to reduce the flow rate of the bypass pipe if the flow rate of the water supply pipe to the heat exchanger is substantially constant by a control valve installed at the branch of the bypass pipe and the hot water supply pipe. lost. In this way, since the amount of unheated water is reduced, the tapping temperature after joining is increased, so that the final tapping temperature can be matched with the set temperature even if the gas burner is burned at a smaller burn rate than the maximum allowed burn rate. Hot water supply in the temperature range is possible.

In addition, if the blockage of the combustion chamber supply and exhaust passage is severe enough, it is difficult to supply sufficient combustion air to the gas burner, so that the degree of obstruction of the supply and exhaust passage is detected and the allowable maximum combustion amount of the gas burner is limited according to the degree of occlusion. Has been developed by the inventors of the present invention. In the hot water heater as described above, in a state in which sufficient gas supply to the gas burner is not possible, the occurrence of a combustion failure can be prevented because a situation in which a large amount of fuel is suddenly burnt and burned in the gas burner is eliminated.

However, as described above, when the tapping temperature does not reach the set temperature even when burning with the allowable maximum combustion amount of the gas burner, it has been found that reducing the amount of water passing through the bypass pipe causes the following problems.

In other words, if the water supply amount (not heated) of the bypass pipe is reduced, the tapping temperature of the set temperature can be obtained with the combustion amount less than the allowable maximum combustion amount, but if the set temperature is significantly lowered in that state, the combustion amount of the gas burner is the tapping temperature. Is also reduced to match the set temperature. In this case, since the water flow rate of the water heated in the heat exchanger is almost constant as described above, the temperature of the heat exchanger is lowered, and if the temperature is lowered below a certain temperature, there is a problem that drainage tends to occur.

In particular, when the allowable maximum combustion amount of the gas burner is limited according to the degree of occlusion of the supply / exhaust passage, the combustion amount of the gas burner is limited to low, so that the above problems are easily caused. The generation of the drain causes clogging of the supply / exhaust passage as described above, and thus there is a concern that good combustion cannot be performed.

The present invention solves the above problems, and when the tapping temperature does not reach the set temperature even when burning at the maximum burned amount of the gas burner, in the hot water heater to reduce the amount of water passing through the bypass pipe, it is possible to prevent the occurrence of drainage It is for the purpose of providing a water heater.

1 is a system configuration diagram of a hot water heater of one embodiment of the present invention.

2 is a block diagram illustrating main parts of a hot water heater according to one embodiment of the present invention.

3 is a diagram for explaining the quantity control of the hot water heater according to the embodiment of the present invention.

4 is a diagram showing the relationship between the rotation speed correction value of the hot water heater combustion fan of one embodiment of the present invention and the degree of blockage of the supply and exhaust passage.

* Explanation of symbols for main parts of the drawings

3: hot water heater 4: gas burner

5: combustion chamber 12: bypass euro

40: bleaching degree detecting means 41: combustion amount limiting means

43: drain monitoring means 44: combustion control means

45: water flow rate control means 46: drain prevention means

In order to achieve the above object, the hot water heater of the present invention includes a gas burner accommodated in a combustion chamber, a heat exchanger heated by combustion of the gas burner, a water supply passage provided to pass through the heat exchanger, and the upstream side of the heat exchanger. A bypass path branched from a water supply passage and joined to the water supply passage on the downstream side of the heat exchanger, and tapping temperature detection means formed in the water supply passage on the downstream side of the bypass passage and the water supply passage; Combustion control means for controlling the combustion of the gas burner while supplying or feeding the gas burner so that the tapping temperature detected by the temperature detecting means coincides with the set temperature, and burns the gas with the maximum allowable combustion amount of the gas burner; When the temperature does not reach the set temperature, the amount of water flowing through the heat exchanger is almost constant and In a hot water heater having a water flow rate control means for reducing the amount of water flowing into the bypass, drain monitoring means as a heat exchanger thermistor for monitoring the drain generation of the heat exchanger, and the drain monitoring means may cause the drain to be generated or generated. Is determined, the drain preventing means for increasing the amount of water passed to the bypass reduced by the amount of water controlling means to the amount of water flowing out of which the drain is eliminated, wherein the drain monitoring means includes: The drain generation of the heat exchanger can be monitored by the tapping temperature of the heat exchanger upstream of the confluence of the furnace and the feedwater furnace, the fan temperature of the heat exchanger, or the exhaust temperature of the combustion chamber. Surveillance can be facilitated.

In the present invention, when the amount of water flowing into the bypass is increased by the drain preventing means, the amount of water flowing into the bypass is already increased to a predetermined maximum water flowing amount, or up to the predetermined maximum water flowing amount. Even if the amount of water passed to the bypass is increased, there may be a case where drain generation or a concern of draining is still detected by the drain monitoring means.

Thus, in the present invention, the drain preventing means further generates or attempts to generate a drain by the drain monitoring means in a state where the amount of water flowing into the bypass is increased to a predetermined maximum amount of water flowing into the bypass. When it is grasped, it is provided with means for increasing the combustion amount of the gas burner to the combustion amount at which generation of the drain is eliminated irrespective of the set temperature.

In the present invention, in general, the drain of the heat exchanger is generated when the temperature of the heat exchanger falls below a certain temperature, and the tapping temperature of the heat exchanger upstream of the confluence place between the bypass passage and the water supply passage. Alternatively, the fan temperature of the heat exchanger or the exhaust temperature of the combustion chamber depends on the temperature of the heat exchanger.

Further, in the present invention, the blockage degree detecting means for detecting the degree of occlusion of the supply and exhaust passage communicating with the combustion chamber, and the allowable maximum of the gas burner in accordance with the degree of occlusion of the supply and exhaust path detected by the occlusion degree detecting means. And a combustion amount limiting means for limiting the combustion amount.

An embodiment of the present invention will be described with reference to FIGS. 1 to 4.

FIG. 1 is a system configuration diagram of the water heater of the present embodiment, FIG. 2 is a block diagram showing the main parts of the water heater of FIG. 1, FIG. 3 is a diagram for explaining the quantity control of the water heater of FIG. 1, and FIG. Fig. 1 is a diagram showing the relationship between the rotation speed correction value of the combustion fan of the hot water heater and the degree of blockage of the supply and exhaust passage.

It demonstrates with reference to FIG.

The hot water heater of this embodiment is provided with the hot water heater main body 1 and the remote control 2 connected to this main body 1.

The water heater main body 1 includes a water supply passage 3, a gas burner 4, a combustion chamber 5 containing the gas burner 4, and a combustion fan 6 for supplying combustion air into the combustion chamber 5; ), A control unit 7 and a feed furnace 8 for feeding combustion gas into the gas burner 4.

The water supply passage 3 is composed of a raw water supply pipe 9, a heat exchange engine 10, and a tapping pipe 11, and a bypass pipe (bypass path) 12 is connected in parallel to the heat exchange engine 10. It is.

The upstream side is connected to the tap water, and the downstream side is connected to the inlet of the electric quantity control device 13 on the raw water supply pipe 9. The water supply pipe 9 is provided with a water drainage plug 14 for use as a water filter, a water supply sensor 15, and a water supply thermistor 16 from an upstream side. The water quantity sensor 15 transmits a pulse in accordance with the quantity of water flowing in the water supply pipe 8 in a vane fashion. The water supply thermistor 16 is for detecting the water supply temperature.

The heat exchange engine 10 has an upstream inlet side connected to an outlet side of the electric water quantity control device 13, and an intermediate portion thereof passes through a heat exchanger 17 provided above the gas burner 4, and the downstream outlet side thereof It is connected to the tapping pipe 11. The heat exchanger 17 is heated by the combustion of the gas burner 4, whereby water flowing in the heat exchanger 10 passes through the heat exchanger 17. Moreover, the overheat prevention apparatus 18 is provided in the outer wall, and the thermistor 19 for heat exchangers as a drain monitoring means is provided in the downstream outlet side. The thermistor 19 for heat exchangers detects the tapping temperature of the water which passed the heat exchanger 17.

The bypass pipe 12 has an upstream inlet side connected to the other side outlet side of the electric water flow control device 13 and branched from the water supply passage 3 on the upstream side of the heat exchange engine 10, and the downstream end of the hot water pipe 11. Is connected to an upstream side (downstream end side of the heat exchange engine 10) and joins the water supply passage 3 on the downstream side of the heat exchange engine 10.

The tapping pipe 11 discharges a freezing prevention heater 20 for preventing freezing, a tapping temperature thermistor 21 for detecting tapping temperature 21 (tapping temperature detection means), a water drain stopper 22 combined with an overpressure safety valve, and hot water. The hot water stopper 23 for making it soaking is provided from the upstream side to the downstream side. The tapping temperature thermistor 21 detects the tapping temperature of the hot water flowing through the tapping pipe 11 of the feedwater passage 3 on the downstream side of the water supply passage 3 and the bypass pipe 12. The hot water stopper 23 is a hot water stopper for adjusting the amount of hot water discharged from the tap (not shown) disposed in the kitchen or bathroom.

The electric quantity control device 13 is controlled by the control unit 7 and passes through the total amount of water passing through the raw water supply pipe 9 (= total amount of water passing through the tapping pipe 11) and the heat exchange engine 10. The ratio of the amount of heat exchanged water and the amount of bypass water passing through the bypass pipe 12 to reach the tapping pipe 11 without passing through the heat exchange engine 10 is adjusted.

In this case, when the opening degree of the hot water stopper 23 is constant, the electric flow rate controller 13 is shown in FIG. 3 in accordance with the operation amount (operation angle of the valve not shown) of the electric quantity control apparatus 13. Adjust the quantity with the quantity characteristic as shown. That is, if the operation amount of the electric quantity control device 13 is reduced from the maximum operation amount S _max , the total amount of water passing through the raw water supply pipe 9 will be at _a predetermined ratio up to the operation amount S _a (<S _max ) according to the decrease in the operation amount. is lowered, the operation amount of the operation amount S is decreased to less than _a smaller percentage than the percentage decrease of the manipulated variable to _a S. The amount of heat exchanged water passing through the heat exchange engine 10 (the amount of water heated in the heat exchanger 17) is independent of the operation amount until the operation amount of the electric water quantity control device 13 is the maximum operation amount S _max to the operation amount S _a . It is kept constant and falls at the same rate as the reduction ratio of the total amount of water at the operation amount of the operation amount S _a or less. Therefore, in the operation amount in the range of S _a ≤ operation amount ≤ S _max , the bypass amount flowing through the bypass pipe 12 (which is equal to the total water amount minus the heat exchange water amount) decreases as the operation amount decreases. In addition, in this embodiment, when the hot water supply stopper 23 is fully opened in the maximum operation amount _Smax of the electric quantity control apparatus 13, the total amount of water equivalent to No. 16, for example, can be obtained.

The feed station 8 is provided with an original solenoid valve 24 and a governor proportional solenoid valve 25 in order from the upstream side thereof, and its downstream end is provided with a combustion chamber for supplying fuel gas to the gas burner 4. 5) is introduced. The governor proportional solenoid valve 25 is energized and controlled by the control unit 7, and continuously changes the amount of fuel gas fueled in accordance with the amount of energization. The original solenoid valve 24 opens and closes by the control of the control unit 7, and interrupts the power supply to the gas burner 4 and interrupts it.

Also, in FIG. 1, reference numeral 26 denotes an ignition electrode, 27 denotes an igniter, 28 denotes a frame rod for detecting a combustion flame, 29 denotes a thermal fuse for preventing overheating, and 30 denotes an operation of the cryoprotective heater 20. Low temperature sensing switch. In the combustion chamber 5, an exhaust passage 32 (exhaust exhaust passage) for collecting and discharging the combustion exhaust gas 31 to an upper portion thereof is extended, and an air supply passage 33 in which the combustion fan 6 is installed is provided. R) is in communication. An extension duct, not shown, is connected to the exhaust passage 32 as necessary.

The remote controller 2 is provided with a temperature setting switch 34, an operation switch 35, an indicator (not shown), and the like.

Next, a description will be given with reference to FIG.

The control unit 7 is provided with a microcomputer (not shown). As a main functional configuration, the necessary combustion amount calculation unit 36 for calculating the required combustion amount of the gas burner 4 and the combustion fan 6 are provided. Fan control unit 37 for controlling the control, correction value calculation unit 38 for calculating a correction value for correcting the rotation speed of the combustion fan 6, and proportional valve control unit for energizing and controlling the governor electromagnetic proportional valve 25 (39), a blockage degree detecting unit 40 (blocking degree detecting means) for detecting the degree of occlusion of the exhaust passage 32 or the air supply passage 33, and a combustion amount for appropriately controlling the allowable maximum combustion amount of the gas burner 4; The control unit 41 (combustion amount control unit), the water quantity control unit 42 for controlling the amount of water by the electric quantity control unit 13, and the drain monitoring unit 43 for monitoring the drain generation of the heat exchanger 10; ).

Here, in accordance with the configuration of the present invention, the required combustion amount calculation unit 36, the fan control unit 37, the correction value calculation unit 38, and the proportional valve control unit 39 are the combustion fan 6 and the governor electromagnetic proportional valve. The combustion control means 44 is formed together with the reference numeral 25, and the water quantity control part 42 constitutes the water flow rate control means 45 and the drain preventing means 46 together with the electric power amount control device 13.

The required combustion amount calculating unit 36 is configured to supply the water supply temperature or quantity detected by the water supply thermistor 16, the water quantity sensor 15, and the tapping thermistor 21 (total water quantity), the tapping temperature and the electric water quantity control device 13. Based on the operation amount, the required combustion amount of the gas burner 4 for matching the tapping temperature to the set temperature set by the temperature setting switch 34 of the remote controller 2 is calculated using a predetermined calculation formula or the like.

The fan control unit 37 is configured to supply an appropriate amount of combustion air to the gas burner 4 in the combustion chamber 5 corresponding to the required combustion amount determined by the required combustion amount calculation unit 36 during combustion of the gas burner 4. The combustion fan 6 is set so that the target rotational speed of the combustion fan 6 is set and the actual rotational speed of the combustion fan 6 detected by the rotational speed sensor 48 provided in the combustion fan 6 matches the target rotational speed. Feedback control the number of revolutions. In this case, the fan control unit 37, when the exhaust passage 32 or the air supply passage 33 is not blocked, the rotation speed of the combustion fan 6 that can supply the appropriate amount of combustion air corresponding to the required combustion amount, The reference target rotational speed determined in accordance with the required combustion amount in advance is obtained by using a map or a table, and the obtained reference target rotational speed is multiplied by the correction value calculated as described later by the correction value calculation unit 38. By correcting, the target rotational speed (when the correction value is '1' coincides with the reference target rotational speed) is set.

The correction value calculating part 38 changes the fan current of the combustion fan 6 (the current of the motor which drives the combustion fan 6) according to the blockage degree of the exhaust path 32 or the supply air path 33, If the rotational speed is the same, the rotational current correction value of the combustion fan 6 is based on the detection fan current obtained from the current sensor 49 which detects the fan current by using a decrease in the fan current as the degree of occlusion increases. For example, get it every 20ms. In this case, the correction value calculation unit 38 sets the fan current flowing when the exhaust passage 32 or the air supply passage 33 is not occluded, and is determined in advance corresponding to each rotation speed of the combustion fan 6. Based on the current, the correction value is obtained by using a predetermined equation or the like according to the degree of decrease of the detection fan current (which is dependent on the degree of occlusion) relative to the reference fan current. The correction value thus obtained is obtained, for example, by the value as shown in FIG. 4 in accordance with the degree of occlusion of the exhaust passage 32 or the air supply passage 33. The target rotational speed is obtained by multiplying the correction value H by the fan control unit 37 by the reference rotational speed, and the target rotational speed is determined by the current occlusion degree of the exhaust passage 32 or the air supply passage 33. The rotation speed of the combustion fan 6 which can supply an appropriate amount of combustion air to the gas burner 4 corresponding to the required combustion amount.

The proportional valve control unit 39 supplies the combustion gas to the gas burner 4 in an amount corresponding to the amount of combustion air supplied to the gas burner 4 by the combustion fan 6. The amount of energization to the governor electromagnetic proportional valve 25 is determined according to the actual rotational speed of the combustion fan 6 detected by the gas fan, and the gas burner 4 is controlled by controlling the energization to the governor electromagnetic proportional valve 25 based on the energization amount. The gas burner 4 is supplied with a combustion gas in an amount corresponding to the air supply amount of the combustion air supplied to the gas. In this case, the proportional valve control part 39 is an amount which is suitable for the amount of combustion air supplied at the current rotational speed of the combustion fan 6 when the exhaust passage 32 or the air supply passage 33 is not blocked. The reference energization amount to the governor proportional solenoid valve 25 which can supply the combustion gas of the combustion gas is determined by using a predetermined map or table according to the actual rotation speed of the combustion fan 6 detected by the rotation speed sensor 48. The amount of current supplied to the governor electromagnetic proportionality valve 25 is determined by dividing the reference current amount by the correction value H obtained by the correction value calculating means 38. By energizing the governor electromagnetic proportional valve 25 with the amount of energization determined in this way, the fuel gas in an amount corresponding to the air supply amount of the combustion air is supplied to the gas burner 4. As described above, since the rotation speed of the combustion fan 6 is controlled by the fan control unit 37 at the target rotation speed and is controlled by the air supply amount of combustion air corresponding to the required combustion amount, the governor as described above. By energizing and controlling the electromagnetic proportional valve 25, the combustion gas of the amount corresponding to the required combustion amount is supplied to the gas burner 4 as a result. In addition, when it is not the fan lead type as mentioned above, it is not necessary to divide the reference electric supply amount to the governor proportional solenoid valve 25 by the correction value H. As shown in FIG.

The occlusion degree detection unit 40 grasps the occlusion degree of the exhaust passage 32 or the air supply passage 33 according to the relationship as shown in FIG. 4 by the correction value H obtained by the correction value calculating section 38. do. For example, if the correction value H = 1.1, the degree of occlusion is found to be 60%.

The combustion amount limiting section 41 limits the maximum allowable combustion amount of the gas burner 4 according to the degree of occlusion detected by the blockage degree detecting unit 40, and sets the limited allowable maximum combustion amount to the fan control unit 37 or the proportional valve control unit. (39) is indicated. In this case, the limit of the maximum allowable combustion amount is, for example, when the detected degree of occlusion is 60% or more and less than 65%, the allowable maximum combustion amount of the gas burner 4 is limited to the combustion amount equivalent to No. 14, and 65% or more and 70%. If less, the maximum allowable combustion amount is made to be limited to the combustion amount equivalent to No. 12. The fan control unit 37 and the proportional valve control unit 39 are configured to allow the maximum amount of combustion regardless of the required amount of combustion when the amount of required combustion is likely to exceed the maximum allowable amount of combustion provided by the combustion amount limiting portion 41. The air supply and the fuel supply are controlled through the combustion fan 6 and the governor electromagnetic proportional valve 25 so as to burn the gas burner 4. The maximum allowable combustion amount is limited in this way because an upper limit is formed on the rotation speed correction value of the combustion fan 6. That is, the combustion air corresponding to the required combustion amount can be supplied by correcting the rotation speed of the combustion fan 6 during the closing of the gust. However, if the correction value is increased, the combustion air is temporarily burned when the gust is stopped. Since it greatly increases with respect to the amount of gas supplied, the rotation speed correction value of the combustion fan 6 is limited in order to avoid this. Therefore, when the correction value exceeds the upper limit, the allowable maximum combustion amount is limited without increasing the rotation speed of the combustion fan 6 even if the capacity of the combustion fan 6 is still marginal.

When the gas burner 4 is being burned at the maximum allowable combustion amount determined by the combustion amount limiting section 41, the amount of electricity supplied to the governor electromagnetic proportional valve 25 by the proportional valve control section 39 is determined. When the amount of energization that makes the combustion gas of a quantity corresponding to the maximum allowable combustion amount is made, the tapping temperature detected by the tapping temperature thermistor 21 is set by the temperature setting switch 34 of the remote controller 2. If not reached, the amount of operation (see FIG. 3) of the electric quantity control device 13 is controlled so as to reduce the bypass amount of the bypass pipe 12 by a predetermined amount. However, when the instruction | command mentioned later is given by the drain monitoring part 43, the quantity control part 42 controls the operation amount of the electric-power amount control apparatus 13 so that a bypass quantity may increase by a predetermined amount on the contrary.

The drain monitoring unit 43 monitors the drain generation of the heat exchanger 17 based on the tapping temperature of the hot water in the heat exchange engine 10 passing through the heat exchanger 17 detected by the heat exchanger thermistor 19. do. In this case, when the tapping temperature of the heat exchange engine 10 becomes 48 degrees C or less, the drain monitoring part 43 judges that there is a possibility that drainage may generate | occur | produce in the heat exchanger 17, and the quantity control part 42 Increasing the bypass amount.

Next, operation | movement of the hot water supply time (during combustion of the gas burner 4) of the hot water heater of this embodiment is demonstrated.

At the time of hot water supply, the tapping temperature of the tapping pipe 11 detected by the tapping temperature thermistor 21 is set by the required combustion amount calculating part 36 of the control unit 7. The required combustion amount of the gas burner 4 for matching with the set temperature set by the above is calculated every time. As described above, the fan control unit 37 of the control unit 7 basically rotates the target rotational speed of the combustion fan 6 in accordance with the required combustion amount and the correction value H calculated by the correction value calculation unit 38. And the feedback control so that the combustion fan 6 rotates at the target rotational speed, the combustion fan 6 is supplied with the appropriate amount of combustion air corresponding to the required combustion amount to the combustion chamber 5 by the combustion fan 6. In addition, the proportional valve control unit 39 determines the amount of energization to the governor electromagnetic proportional valve 25 according to the rotation speed of the combustion fan 6 and the correction value H detected by the rotation speed sensor 48 as described above. By energizing the governor electromagnetic proportional valve 25 with the amount of energization, the amount of combustion commensurate with the amount of combustion air supplied by the rotation speed of the combustion fan 6 controlled to the target rotation speed as described above. The gas is supplied to the gas burner 4. As a result, the gas burner 4 is burned to the required combustion amount, and the combustion amount of the gas burner 4 is controlled so that the tapping temperature of the tapping pipe 11 matches the set temperature.

In addition, at least at the first time of operation of the hot water heater, the operation amount of the electric water quantity control device 13 is set to a maximum operation amount S _max (see FIG. 3), for example, to obtain a total water amount equivalent to No. 16 (at this time, The maximum number of bypasses) and the allowable maximum combustion amount of the gas burner 4 are also the combustion amount equivalent to No. 16.

On the other hand, when hot water is supplied in a state in which the exhaust passage 32 or the air supply passage 33 is blocked to some extent due to the aging use of the water heater, the degree of blockage of the control unit 7 is detected. Is determined based on the correction value H of the number of revolutions of the combustion fan 6, and the allowable maximum combustion amount of the gas burner 4 is limited by the combustion amount limiting portion 41 according to the detected degree of occlusion. (The maximum allowable combustion amount is reduced).

In such a state where the maximum allowable combustion amount is limited, for example, when the set temperature is set relatively high, even if the gas burner 4 is burned at the limited allowable maximum combustion amount in the state where the bypass water is large, the tapping of the tapping pipe 11 is performed. It may happen that the temperature cannot be raised to the set temperature.

In such a case, the water quantity control unit 42 of the control unit 7 gradually reduces the amount of operation of the electric water quantity control device 1 by a predetermined value, thereby reducing the bypass amount by a predetermined value. For this reason, since the amount of unheated water joined in the bypass pipe 12 to the heated hot water flowing in the heat exchange engine 10 decreases, the temperature (heating temperature) of the hot water flowing through the tapping pipe 11 increases. . In this case, the reduction control of the bypass water amount by the water quantity control unit 42 is stopped when the tapping temperature of the tapping pipe 11 matches the set temperature. Then, if the tapping temperature exceeds the set temperature, the required combustion amount of the gas burner 4 becomes smaller than the current maximum allowable combustion amount and the combustion amount of the gas burner 4 is reduced.

Moreover, the operation | movement which reduces the bypass amount in this way may be performed, for example, when the set temperature is set considerably high in the state which has a large total amount of water, even if the allowable maximum combustion amount of the gas burner 4 is not reduced. However, in particular, as the degree of obstruction of the exhaust passage 32 and the air supply passage 33 becomes more severe, the allowable maximum combustion amount is lowered, so that an operation of reducing the bypass amount tends to occur.

When the set temperature is relatively low, for example, in a state where the bypass water is reduced in this way, the required combustion amount of the gas burner 4 for matching the tapping temperature of the tapping tube 12 to the set temperature is large when the bypass amount is large. Since it is lower than that, the combustion amount of the gas burner 4 is controlled in a relatively low state.

In such a state, since the temperature of the heat exchanger 17 is not very high, it will be in the state which drainage is easy to generate | occur | produce. At this time, the drain monitoring unit 43 of the control unit 7 detects the tapping temperature of the heat exchange engine 10 by the heat exchanger thermistor 19, and the detection temperature is predetermined as a threshold temperature for drain generation. When the temperature (for example, 48 ° C.) or less is reached, the water quantity control unit 42 instructs the increase of the bypass amount.

When the water quantity control unit 42 receives the instruction, the water quantity control unit 42 gradually increases the operation amount of the electric water quantity control device 13 by a predetermined amount to increase the bypass amount by a predetermined amount. For this reason, since the amount of unheated water joined by the bypass pipe 12 to the heated hot water flowing in the heat exchange engine 10 increases, the temperature (heating temperature) of the hot water flowing through the tapping pipe 11 is lowered. . When the tapping temperature is lower than the set temperature, the required combustion amount of the gas burner 4 is increased, so that the combustion amount of the gas burner 4 is increased. Thus, the temperature of the heat exchanger 17 rises. In this case, even if the required combustion amount of the gas burner 4 increases, and as a result, the allowable maximum combustion amount limited by the degree of occlusion or the like may be exceeded, there is no particular problem. That is, in the hot water heater limiting the amount of combustion according to the degree of occlusion as described above, although the capacity of the combustion fan 6 is still marginal, if the rotation speed correction value of the combustion fan 6 is large, the gusts or the like stop and the degree of occlusion When the gas is released, the combustion air temporarily increases significantly, and there is a risk of misfire, etc., so that the required combustion amount of the gas burner 4 exceeds the allowable maximum combustion amount limited by the degree of occlusion so as to prevent drainage. Correcting the rotation speed of the combustion fan 6 has no combustion phase or trouble.

In the increase control of the bypass amount by the water quantity control unit 42, until the increase instruction by the drain monitoring unit 43 is resolved, that is, the detection temperature of the heat exchanger thermistor 19 is set to the predetermined temperature 48. Up to a degree Celsius), whereby the bypass amount is finally controlled to the amount where no drain is generated. In the hot water heater of the present embodiment, when the operation of the hot water heater continues to be stopped for more than a predetermined time (for example, 8 minutes) or the like, the electric quantity control device 13 controlled by the water quantity control unit 42 as described above. ) MV returns to the original MV.

By the way, in the increase control of the bypass amount as described above, the operation amount of the electric quantity control device 13 is already at the maximum operation amount S _max , or the increase instruction by the drain monitoring unit 43 is not resolved. When the amount of operation of the electric quantity control device 13 is increased to the maximum operation amount S _max , it is impossible to increase the bypass amount any more because the bypass amount becomes the maximum amount. For this reason, in the present embodiment as described above, the water quantity control unit 42 instructs the required combustion amount calculation unit 36 to forcibly increase the required combustion amount. At this time, the required combustion amount calculation unit 36 gradually increases the required combustion amount regardless of the set temperature of the tapping temperature. As a result, the combustion amount of the gas burner 4 gradually increases, so that the temperature of the heat exchanger 17 rises. The increase in the combustion amount of the gas burner 4 is performed until the increase instruction by the drain monitoring unit 43 is resolved and the forced increase instruction of the combustion amount by the water quantity control unit 42 is eliminated, that is, the heat exchange. Until the detection temperature of the conventional thermistor 19 becomes above the predetermined temperature (48 ° C), drain generation is eliminated by this. In this case, since the combustion amount of the gas burner 4 is increased regardless of the set temperature, the tapping temperature is higher than the set temperature, but hot water supply can be continued.

By controlling the quantity of water control as described above and controlling the combustion amount of the gas burner 4, it is possible to reliably prevent the drain of the heat exchanger 17. Particularly, when the exhaust passage 32 or the air supply passage 33 is blocked, the allowable maximum combustion amount of the gas burner 4 is limited, so that the bypass amount is reduced even at a set temperature which is not so high and the gas burner 4 As the amount of combustion decreases, drainage tends to occur, and if drainage occurs, the exhaust passage 32 may promote the blockage of the air supply passage 33, but as described above, the amount of bypass is increased and the amount of combustion is increased, If the bypass amount is the maximum amount and cannot be increased further, the amount of combustion is forcibly increased, so that the generation of drain can be prevented and the above problems do not occur.

In the hot water heater of the present embodiment, when the degree of occlusion grasped by the degree of obstruction detection unit 40 becomes 80% or more, for example, the gas burner 4 is burned under the control of the control unit 7. Hot water supply operation is stopped (processing such as closing of the solenoid valve 24 is performed).

Moreover, in the hot water heater of this embodiment, pre-purge is performed by the combustion fan 6 at the start of a hot water operation (combustion operation of the gas burner 4), and it obstruct | occludes based on the fan current at that time. When the degree of occlusion at this time exceeds 80%, for example, the hot water supply operation is stopped without ignition of the gas burner 4.

In the above-described embodiment, the drain generation is monitored based on the tapping temperature of the heat exchanger 10. However, the fan temperature of the heat exchanger 17 and the temperature of the combustion exhaust gas of the gas burner 4 are also measured. The drain generation may be monitored based on the fan temperature or the combustion exhaust gas temperature since it is closely related to the drain generation.

In the present embodiment, the degree of occlusion of the exhaust passage 32 and the air supply passage 33 is determined by the rotation speed correction value H of the combustion fan 6 determined based on the fan current. The air volume may be detected directly, or the actual air volume (air supply amount) of the exhaust passage 32 or the air supply passage 33 may be detected using a airflow sensor, and the degree of occlusion may be determined based on the detected air volume. have.

In addition, in this embodiment, although the allowable maximum combustion amount of the gas burner 4 was restrict | limited by the blockage of the exhaust passage 32 and the air supply passage 33, the hot water heater of the type which does not restrict such an allowable maximum combustion amount is shown. The present invention can also be applied to.

According to the present invention, the combustion amount of the gas burner is controlled by the combustion amount control means so that the tapping temperature detected by the tapping temperature detecting means is equal to a set temperature, and at this time, the gas burner is the maximum allowable combustion amount of the gas burner. When the tapping temperature does not reach the set temperature even after burning, the tapping temperature of the set temperature can be obtained by reducing the amount of water flowing into the bypass by the water flow rate controlling means. Then, in the state where the amount of water passed to the bypass is reduced, for example, when the set temperature is significantly lowered, the combustion amount of the gas burner is greatly reduced by the combustion control means. When the amount of water flowing into the bypass is reduced by the water flow rate controlling means and the combustion amount of the gas burner is reduced, when the drain generation means or the possibility of occurrence of drainage is detected by the drain monitoring means. The amount of water passed to the bypass is increased by the drain preventing means. At this time, since the tapping temperature is lowered by increasing the amount of water passed to the bypass, the combustion control means increases the burning amount of the gas burner to increase the tapping temperature. Therefore, the temperature of a heat exchanger rises and the drain generation is eliminated. Then, the drain preventing means controls the amount of water flowing into the bypass so that the state is maintained.

Therefore, according to the present invention, when a drain generation or a concern of generation occurs, the combustion amount of the gas burner may be increased so that the set temperature and the tapping temperature coincide with each other, thereby raising the temperature of the heat exchanger to a temperature at which the drain does not occur. Therefore, drain generation can be prevented reliably.

In addition, when the drainage occurs or there is a concern that the drainage occurs in a state where the water flow rate to the bypass is increased to the maximum water flow rate, the combustion amount of the gas burner is increased irrespective of the set temperature so that the drainage temperature is not generated. By raising to the temperature which is not, the generation | occurrence | production of drain can be reliably prevented. In this case, the tapping temperature is higher than the set temperature because the combustion amount of the gas burner is increased regardless of the set temperature. However, since the burning amount of the gas burner is increased until the drain is released, the tapping temperature is larger than the set temperature. The hot water supply can be continued while preventing the drain from occurring without being raised.

In addition, since the combustion amount of the gas burner is limited when the blockage of the aeration passage proceeds, it is easy to generate a drain due to the temperature decrease of the heat exchanger. However, as described above, the drain monitoring means may cause the drain to occur or occur in the heat exchanger. Is found, the amount of water passed to the bypass is increased by the drain preventing means and the amount of combustion of the gas burner is increased by the combustion amount control means, so that drainage of the heat exchanger is prevented.

Therefore, even if drainage tends to occur as described above, when the drainage or the occurrence of drainage occurs, the number of bypass passages is increased as described above, and the combustion amount of the gas burner is increased, thereby facilitating the blockage of the supply and exhaust passage. It is possible to effectively prevent the generation of a drain which may be a concern.

Claims (3)

A gas burner accommodated in a combustion chamber, a heat exchanger heated by combustion of the gas burner, a water supply passage provided to pass through the heat exchanger, and branched from the water supply passage upstream of the heat exchanger to the downstream side of the heat exchanger. By-pass paths joined to the feed passage, tapping temperature detection means formed in the feed passage on the downstream side of the bypass passage and the feed passage, and tapping temperature detected by the tapping temperature detection means are set to a preset temperature. Combustion control means for controlling the combustion of the gas burner while supplying and feeding the gas burner so as to coincide with the gas burner, and when the tapping temperature does not reach a set temperature by burning at an allowable maximum combustion amount of the gas burner, passing through the heat exchanger. Water flow rate control water which makes the water flow rate to the water supply passage to be substantially constant, and reduces the water flow rate to the bypass passage. A hot water heater having a stage, comprising: a drain monitoring means as a thermistor for a heat exchanger for monitoring the drain generation of the heat exchanger, and the water flow rate control means when the occurrence or concern of drainage is detected by the drain monitoring means. And a drain preventing means for increasing the reduced amount of water flowing into the bypass path to a amount of water flowing out of the drain, wherein the drain monitoring means comprises: a heat exchanger at an upstream side of the confluence of the bypass path and the water supply path; Hot water heater characterized in that for monitoring the occurrence of the drain of the heat exchanger by the tapping temperature of the heat exchanger, the fan temperature of the heat exchanger or the exhaust temperature of the combustion chamber. 2. The drain preventing means of claim 1, wherein when the drain monitoring means detects or causes a drain to be detected by the drain monitoring means in a state where the amount of water passed to the bypass increases to a predetermined maximum amount of water passed to the bypass, And a means for increasing the combustion amount of the gas burner to the combustion amount at which the drain is eliminated regardless of the set temperature. The maximum allowable combustion amount of the gas burner according to claim 1, wherein the occlusion degree detecting means for detecting the occlusion degree of the supply / exhaust passage communicating with the combustion chamber, and the occlusion degree of the supply / exhaust passage detected by the occlusion degree detecting means. Hot water heater, characterized in that provided with a combustion amount control means for limiting.

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